JP6652564B2 - How to install line filters on line filters and system cables - Google Patents

Description

  The present invention relates to a line filter and a method for installing a line filter on a system cable.

  A line filter is a type of electronic filter and is located between an electronic device and an external line, or on any line that interconnects electronic devices in the system. Line filters are commonly used to attenuate conducted radio frequency (RFI), also known as electromagnetic interference (EMI) between external lines and electronics, or between electronics in a system.

  Installing a line filter on a system cable requires a high degree of experience and is time consuming. The quality of the connection is essential to ensure proper conduction of the system current to avoid overheating of the terminals. Typically, this line filter comprises a line-side field wiring power terminal on the line side and another field-side wiring power terminal on the load side. These terminals are configured to be connected to the input of the system cable and the output of the system cable. For example, in a three-wire system, the system requires six system cable terminals, each capable of carrying full system current. For each end, the system cable must be prepared with the correct length and the insulation removed, the core end must be finished using a suitable sleeve, and the cable Must be tightened to the terminal with the correct torque. This torque must be rechecked periodically.

  It is an object of the present invention to provide an improved line filter, for example, a line filter that facilitates installation. Another object of the present invention is to provide an improved method of installing a line filter on a system cable.

  This object is solved by a line filter according to claim 1. The above further object is solved by a method according to the second independent claim.

  A line filter is provided configured to be installed on the system cable, wherein the line filter comprises magnetic components, the line filter defines a cable path through the line filter, and the line filter is installed. It is sometimes configured to allow the system cable to be routed along the cable path, which results in magnetic coupling of the system cable to the magnetic components, where the line filter is crimped It comprises a connector and a shunt component, and the insulation displacement connector is tightened during its installation, thereby providing an electrical connection of the system cable to the shunt component.

  From this viewpoint, the description “at the time of installation” may relate to the installation of the above-mentioned line filter to the system cable of the external electronic device. This installation is not at a point during the manufacture of the line filter. The system cable is not part of the line filter itself. The line filter is to be installed on the system cable at some point after the line filter is manufactured, and is performed by a different person than the manufacturer, and specifically, for example, by the installer of the electronic device. Or done by the user.

  The line filter according to the present invention may be a low-pass filter. The line filter can be configured to attenuate high frequency interference, also called electromagnetic interference (EMI). This line filter can be configured to attenuate leakage current. This line filter may be connected between the power grid and the electrical load or between electronic devices in the system, for example, between the motor drive and the motor.

  A line filter according to the present invention can provide electromagnetic compatibility (EMC) between devices. The line filter may include means for removing a ground leak current in a frequency range of 150 Hz to 150 kHz from the system cable.

  This magnetic component may be an inductor core.

  The cable path may be a predetermined path extending through the line filter. Specifically, the cable path may connect the line side of the line filter to the load side of the line filter.

  From this point of view, it is understood that the above description "arranged along the cable path" is implemented by the user of the line filter or the installer of the line filter. In this operation, the system cable can be manually arranged along the cable path. In one embodiment, the system cable can be arranged by pushing the system cable through a line filter along the cable path. However, alternative embodiments of the arrangement of cables along this cable path are possible.

  The insulation displacement connector (IDC) is configured to provide an electrical connection of the system cable to the shunt component. Specifically, the IDC is configured to provide a voltage tap such that small branch currents to the shunt component can be extracted from the system cable. This allows the same voltage to be applied to the system cable and the shunt component.

  The shunt component may include one or more shunt capacitors. The shunt component can be connected between the system cable and a ground terminal or between the phases of the system cable. The line filter may include a plurality of shunt components connected in a ladder-type connection.

  The line filter is magnetically coupled to the system cable and is configured to be electrically connected when installed on the system cable. The line filter includes a line terminal and a load terminal. The internal main power supply line connecting to is not used. Instead, this system cable, which is routed along the cable path, is connected directly to the magnetic component and the IDC during its installation. Thus, the on-site preparation of the field filter wiring of this line filter is completely unnecessary, and the associated costs and labor are saved. This facilitates time-consuming preparation of the field wiring for the installation of the line filter and the terminal connection of the system cable. As a result, the work of installing the line filter on the system cable is greatly facilitated.

  In one embodiment, the line filter according to the present invention comprises an opening, which is installed by pushing the system cable through the opening along the cable path. , The system cable can be arranged. Plugging the system cable through one opening of the line filter and exiting from the other opening, which is the outlet of the system cable from the line filter, comprises This is a particularly simple way of installation. This improves user safety as it allows for quick installation and prevents incorrect installation, eg poor connection to large currents.

  The IDC includes a screw and at least one conductor pin that is stabbed into the system cable when the screw is tightened. The IDC may have only one conductor pin. Alternatively, the IDC may have a plurality of conductor pins.

  Specifically, the conductor pins may be configured to push the insulation of the system cable. As a result, by loosening the screw, the line filter can be removed from the system cable, the pin can be pulled out of the system cable, and the insulation suffers only minor damage .

  The pin may be located at the end of the screw, which is configured to point in the direction of the system cable, or when the line filter is installed on the system cable. Alternatively, it may be arranged to be on the side of the system cable opposite the screw.

  The conductor pins may be configured to be pierced into the insulation of the system cable and protrude into the system cable at a depth ranging from less than 1 mm to several mm. Specifically, this depth may range from 0.01 mm to 20 mm. The system cable may include an inner conductor coated with an insulating material. The conductor pin may be pierced through the insulation and configured to enter the inner conductor.

  The depth into which the pin penetrates into the system cable is designed so that it can be adjusted to provide different conductive properties of the electrical connection of the IDC.

  The magnetic component may be in the shape of an annulus and may be provided with an opening. The cable path described above may pass through an opening in the magnetic component.

  The line filter according to the present invention has no internal conductor wiring. As a result, the cable follows a straight path through the line filter. Thus, the cable path can guide the system cable almost straight through the line filter. This facilitates arranging the system cable by pushing along the cable path described above. Specifically, pushing the system cable along the straight line requires minimal deformation or twisting of the system cable.

  The IDC is configured to extract a branch current from the system cable via an electrical connection of the system cable to the shunt component, wherein the branch current connects the system cable to the shunt component. It is smaller than the power supply current flowing through it. Specifically, the branch current may be several orders of magnitude lower than the current flowing through the system cable. The shunt component of the line filter according to the invention may be designed to draw a relatively small current compared to the current flowing through this system cable. As a result, the power supply current can be very large and the power supply current is not attenuated while the high frequency disturbance branch current is removed from the system cable.

  This branch current may be in the range of 0.1A to 10A. The current flowing through this system cable at the same time can be up to 1000A. Specifically, the current in this system cable may range from 10A to 1000A. Voltages up to 600V can be present on this system cable. The line filter according to the invention can be designed to provide attenuation in the frequency range from 1 kHz to 30 MHz.

  The line filter according to the invention may comprise a plurality of IDCs, each of these IDCs being configured to be tightened during installation, thereby providing an electrical connection to the shunt component of the system cable. Connection is provided. Specifically, the line filter may be configured to be installed on a system cable comprising one or more phases. The line filter may be configured such that when the system cable is disposed along the cable path, all phases of the system cable are magnetically coupled to the same magnetic component; Also, the individual phases can be coupled to separate magnetic components. Further, the line filter can be configured to electrically connect each phase of the system cable to at least one insulation displacement connector. Such a design allows the different phases of the system cable to be electrically connected individually. For example, each IDC may have a different design.

  Further, a line filter according to the present invention may include a plurality of IDCs configured to be connected to the same phase of the system cable. This makes it possible to extract larger branch currents or to connect multiple shunt components.

  Further, the line filter according to the present invention may include a guide member, which guides the system cable along the cable path when the system cable is disposed along the cable path. And configured to hold the system cable in the cable path once the system cable is disposed along the cable path. This guide member may be a plastic part.

  The line filter according to the present invention may be a low-pass filter.

  The IDC can be configured to be connected to the system cable by an airtight connection.

  The IDC can be configured to provide strain relief when connected to the system cable.

  The above-described IDC can be configured to provide a spring action that maintains a constant clamping force for a long time.

  The line filter according to the present invention can be configured to be detachable from the above system cable. Specifically, the line filter can be removed by opening the IDC and removing the system cable from the cable path, for example by pulling the system cable out of the line filter. The line filter can be configured such that upon removal from the system cable, the system cable receives minimal damage where the insulation is pierced. This removal can be performed by a qualified user or installer.

  The line filter according to the invention may comprise a housing, wherein the insulation displacement connector is configured to pierce the system cable at one location provided in the housing. As a result, the area where the system cable is pierced by the insulation displacement connector can be protected by the housing.

  The cable path described above extends through the housing. The above-mentioned magnetic component may be disposed in the housing. The above-described press-connecting connector may be provided in the housing. In particular, the insulation displacement connector may be completely arranged in the housing. The shunt component described above may be disposed in the housing.

  According to another aspect, the present invention relates to an assembly comprising a line filter as described above and a system cable as described above.

Further, the present invention relates to a method of installing a line filter on a system cable, wherein the line filter includes a magnetic component, an IDC, and a shunt component. The method comprises the following steps.
Arranging the system cable along a cable path defined through the line filter, which results in a magnetic coupling of the system cable to the magnetic component.
-Tightening the insulation displacement connector around the system cable, thereby providing an electrical connection of the system cable to the shunt part.

  The line filter used in the method according to the invention may be the same as the line filter described above, and all the functional and structural features disclosed for the line filter above also apply for the method. it can.

Hereinafter, the present invention will be described in more detail with reference to the drawings.
FIG. 2 shows a cross-sectional view of a line filter installed on a system cable. FIG. 3 shows a perspective view of the line filter installed on the system cable. The details of the magnetic component, the cable guide, and the IDC connector are shown in perspective views. The details of the magnetic component, the cable guide, and the IDC connector are shown in perspective views. One alternative construction of the line filter is shown in perspective view, showing the IDC connector, magnetic components, shunt components, and cable guide. FIG. 3 shows a perspective view of one press-connecting connector. FIG. 4 shows a perspective view of one alternative insulation displacement connector.

  FIG. 1 is a sectional view of a line filter 1 installed on a system cable 2. FIG. 2 is a perspective view of the line filter 2 installed on the system cable 2.

  The line filter 1 according to the present invention is a kind of electronic filter, and is disposed between an electronic device (not shown) and a line (not shown) outside the device, and is provided between the external line and the electronic device. Or it is provided to attenuate conducted radio frequency (RFI), also called electromagnetic interference (EMI), between multiple electronic devices in the system.

  This line filter 1 is supplied by the manufacturer without a system cable 2. Upon installation, a suitable system cable is supplied by the installer. Next, the line filter 1 is installed on the system cable 2 by an installer, wherein the line filter 1 is installed between the electronic device and the line outside the electronic device or inside the system. It is arranged between electronic devices. This system cable 2 comprises an insulating material covering the conductive internal material, for example copper.

  The line filter 1 includes a housing 3. This housing 3 is made of a plastic material. Other components of the line filter 1 are disposed in the housing 3. The housing 3 can be mounted on a system cabinet (not shown).

  The present line filter 1 is a low-pass filter. The line filter 1 includes a magnetic component 4 and a shunt component 5 configured as an inductor disposed along the above-described system cable, for example, a shunt capacitor. The line filter 1 is configured to form an LC low-pass filter when the magnetic component 4 and the shunt component 5 are connected to the system cable 2.

The line filter 1 defines a cable path 6 extending through the line filter 1. Specifically, the cable path 6 enters the line filter 1 on the load side 7 and exits the line filter 1 on the line side 8. Since the line filter 1 defines a cable path 6 along which the system cable 2 can be arranged, the line filter 1 must otherwise be electrically connected to the system cable 2. No need to use the internal power cable.

  The line filter 1 is provided with an opening 9a on the load side 7 such that the system cable 2 enters the line filter 1 on the load side 7 through this opening 9a. . Furthermore, the line filter 1 is provided with an opening 10 on the line side 8 such that the system cable 2 exits from the line filter 1 through the opening 10 on the line side 8. ing.

  In the embodiment shown in FIGS. 1 and 2, the system cable 2 comprises three phases 11, 12, 13. The line filter 1 includes three openings 9a, 9b, 9c provided on the load side of the line filter. Further, the line filter 1 has only one opening 10 provided on the line side 8 of the line filter 1. A cable path 6 defined through this line filter 1 connects each of the three openings 9 a, 9 b, 9 c on the load side 7 to one opening 10 on the line side 8. The phases 11, 12, 13 of the system cable 2 enter each of the openings 9a, 9b, 9c on the load side 7 of the line filter 1. Furthermore, all phases 11, 12, 13 of the system cable 2 leave the line filter 1 through one opening 10 on the line side 8.

  Further, the line filter 1 includes a guide member 14 configured to guide the system cable 2 along the cable path 6 when the system cable 2 is disposed along the cable path 6. Have been. The guide member 14 is formed as a single flat tube, in which the phases 11, 12, 13 of the system cable 2 are guided in the same flat tube. The guide member 14 is made of a plastic material.

  Specifically, the system cable 2 can be disposed along the cable path 6 by being pushed into the line filter 1 from the load side 7. In this case, the guide member 14 is configured such that the system cable 2 slides along the guide member 14 so that it is guided along the cable path 6 through the line filter 1. ing. Once the line filter 1 is installed on the system cable 2, the guide member 14 holds the system cable 2 so that its position is along the cable path 6.

  In the embodiments shown in FIGS. 1, 3, and 4, the line filter 1 comprises two magnetic components 4. In an alternative configuration, the line filter 1 may include one or more magnetic components.

  Each of these magnetic components 4 is an annular inductor core. Specifically, these magnetic components 4 are configured to be magnetically coupled to the system cable along the system cable. Each of these magnetic components 4 defines a respective opening 15, wherein the cable path 6 passes through these openings 15. When the system cable 2 is thus arranged along the cable path 6, the system cable 2 extends through the openings 15 of these magnetic components 4. Specifically, all phases 11, 12, 13 of this system cable 2 extend through openings 15 of these magnetic components 4.

  In one alternative construction, these magnetic components 4 may be of any suitable shape providing an opening 15. In an alternative arrangement, the phases 11, 12, 13 of the system cable 2 may pass through separate magnetic components, ie one phase cable 11, 12, 13 for each magnetic component 4.

  When the system cable 2 is disposed to extend through the opening 15 and through the magnetic component 4, a magnetic coupling between the system cable 2 and the magnetic component 4 is established. Specifically, the system cable 2 forms a coupling with the magnetic component 4 and having one winding.

  Further, the line filter 1 includes at least one shunt component 5, for example, a shunt capacitor.

  Further, the line filter 1 includes a press-connecting connector (IDC) 16. This IDC 16 is provided near the load side 7 of the line filter 1. This IDC 16 includes a screw 17 and a conductor pin 18. In the embodiment shown in FIG. 6, the conductor pin 18 is provided at the end of the screw 17 facing the direction of the system cable 2. Thus, the screw 17 and the pin 18 are formed from a single member. The screw 17 is a metal screw. In an alternative configuration, the IDC 16 may be located at any suitable location in the line filter 1.

  Further, a plate 19 is provided near the end of the screw 17 facing the direction of the system cable 2. Further, the IDC 16 includes a cage 20. The plate 19 is configured to press the system cable 2 when the screw 17 is tightened. The system cable 2 is mechanically fixed, for example, is clamped between the plate 19 and the cage 20 when the screw 17 is tightened. The cage 20 comprises a metal block 23 having a thread groove for receiving the screw 17 and a metal belt 24 surrounding the system cable 2.

  Further, when the screw 17 is tightened, the conductor pin 18 is pierced into the insulating material of the system cable 2, thereby establishing an electrical connection to the system cable 2. Specifically, when the conductor pins 18 pierce the system cable 2, the insulating material of the system cable is displaced. Since the system cable 2 is pressed between the plate 19 and the cage 20, it is ensured that the pins 18 are pushed into the conductors of the system cable 2 and that this system cable 2 has good access to the conductive inner material. Electrical connection is provided.

  Further, the IDC 16 has a low current connection point (not shown), and this constant current connection point is connected to the shunt component 5. When the screw 17 is tightened, this IDC 16 provides an electrical connection to the shunt part 5 of the system cable 2. Specifically, the IDC 16 includes a small soldering terminal or a crimp terminal (not shown), and this terminal is configured to make a wiring connection to at least one shunt component 5. The IDC 16 is configured to be a voltage tap of the system cable 2. As a result, when the above-mentioned electrical connection is established, the same voltage as that of the system cable 2 is also applied to the shunt component 5. Furthermore, the above-mentioned electrical connection is configured such that only small branch currents are extracted from the system cable 2 through the conductor pins 18. This branch current may be one digit or more smaller than the power supply current flowing through the system cable 2. This branch current may be in the range of 0.1A to 10A.

  Furthermore, the IDC 16 comprises a plastic housing 21 which provides insulation for this IDC 16. This IDC 16 is configured to provide a hermetic sealing of the system cable 2. This hermetic sealing is formed by the pressure on the system cable 2 of the plate 19 and the cage 20 and by the pressure applied to the conductor pins 18 by the displaced insulation of the system cable 2.

  The depth at which the pins 18 penetrate into the system cable 2 is designed to be adjustable so as to provide the different conductive properties of the electrical connection described above. The pins 18 can project into the conductor of the system cable 2 in less than one millimeter or a few millimeters.

  The system cable 2 comprises three phases 11, 12, 13. This line filter 1 includes three IDCs 16. Each of these IDCs 16 is assigned to one phase 11, 12, 13 of the system cable 2. Specifically, each of these IDCs 16 is configured to electrically connect one phase 11, 12, 13 of the system cable 2 to the shunt component 5.

  In alternative constructions, the system cable 2 may have other numbers of phases. In this case, the line filter 1 includes one IDC 16 and one opening 9 a on the load side 7 for each phase of the system cable 2.

  In an alternative configuration, more than one IDC 16 may be connected to one phase of the system cable 2. As a result, multi-stage shunt components can be connected to the system cable 2. Alternatively or additionally, each IDC 16 may include two or more conductor pins 18 that are stabbed into system cable 2 when screws 17 of each IDC 16 are tightened. It is configured as follows. This structure also allows a larger branch current to be extracted from the system cable 2 via the IDC 16.

  3 and 4 show details of the line filter 1. For the sake of clarity, in particular, neither the housing 3 nor the shunt part 5 of the line filter 1 is shown in FIGS. In particular, the IDC connector 16, the cable guide 14, and the magnetic component 4 are all shown.

  FIG. 5 shows a perspective view of another alternative structure of the present line filter 1. FIG. 5 shows the housing 3 partially transparent for easy understanding.

  This structure shown in FIG. 5 differs from the above-described structure in the structure of the guide member 14. In the configuration shown in FIG. 5, the guide member 14 comprises a plurality of separate tubes 22, where one tube 22 is provided for each phase 11, 12, 13 of the system cable 2.

  FIG. 6 shows a perspective view of the IDC 16 described above.

  FIG. 7 shows one alternative structure of the IDC 16. In the IDC 16 shown in FIG. 7, a conductor pin 18 is provided on the side of the cage 20 opposite to the screw 17. However, the basic functions of the IDC 16 have not been changed. When the screw 17 is tightened, the system cable 2 is thereby pressed between the plate 19 and the cage 20, and the conductor pins 18 are simultaneously pushed into the system cable 2.

  In another alternative configuration, IDC 16 includes two conductor pins 18. The first conductor pin 18 is provided at the end of the screw 17 facing the direction of the system cable 2 as shown in the embodiment of FIG. The second conductor pin 18 is provided on the side of the cage 20 opposite the screw 17 as shown in the embodiment of FIG. By preparing the two conductor pins 18, a larger branch current can be extracted from the system cable 2. No other function changes are required.

1: line filter 2: system cable 3: housing 4: magnetic part 5: shunt part 6: cable path 7: load side 8: line side 9a, 9b, 9c: load side opening 10: line side opening 11 , 12, 13: System cable phase 14: Guide member 15: Opening 16: IDC (IDC)
17: Screw 18: Conductor pin 19: Plate 20: Cage 21: Plastic housing 22 of IDC: Tube 23: Block 24: Belt

Claims (10)

A line filter (1) configured to be installed on a system cable (2) comprising at least one phase (11, 12, 13),
The line filter (1) includes a magnetic component (4),
Said line filter (1) defines a cable path (6) through said line filter (1);
The line filter (1) is configured to insert the system cable (2) along the cable path (6) when installed, whereby the magnetic component (4) of the system cable (2) is inserted. Magnetic coupling to the
Said line filter (1) comprises a press-connecting connector (16) and a shunt component (5), said press-connecting connector (16) being tightened during its installation, whereby said shunt component of said system cable (2) Providing an electrical connection to (5),
When the system cable (2) is disposed along the cable path (6), the line filter (1) is configured such that all phases (11, 12, 13) of the system cable (2) are magnetically separated. It is configured to be magnetically coupled to the component (4),
The line filter (1) is configured such that each of the phases (11, 12, 13) of the system cable (2) is electrically connected to at least one of the press-connecting connectors (16);
Each of the press-connecting connectors (16)
A plastic housing (21) providing insulation of the insulation displacement connector (16);
A screw (17) and at least one conductor pin (18) which is stabbed into the system cable (2) when the screw (17) is tightened;
A cage (20) comprising a metal block (23) having a thread groove for receiving the screw (17), and a metal belt (24) surrounding the system cable (2);
A plate (19) provided near the end of the screw (17) facing in the direction of the system cable (2);
The plate (19) and the cage (20) press the system cable (2) to displace the insulation of the system cable (2), and the conductor by the displaced insulation of the system cable (2). The pin (18) is pressed to provide a hermetic sealing;
A line filter characterized by the above-mentioned. The line filter according to claim 1,
The line filter (1) includes openings (9a, 9b, 9c, 10),
The opening allows the system cable (2) to be pushed through the openings (9a, 9b, 9c, 10) along the cable path (6) during installation. Is configured to be able to be arranged,
A line filter characterized by the above-mentioned. The line filter according to claim 2,
The conductor pin (18) is arranged at the end of the screw (17) configured to face in the direction of the system cable (2) or the conductor pin (18) is connected to the line When the filter (1) is installed on the system cable (2), the filter (1) is arranged to be on the side of the system cable (2) opposite to the screw (17),
A line filter characterized by the above-mentioned. The line filter according to claim 3,
The conductor pin (18) is configured to be inserted into the system cable (2) and protrude into the system cable (2) at a depth in a range of 0.01 mm to 20 mm. Characteristic line filter. The line filter according to any one of claims 1 to 4,
The magnetic component (4) is annular and has an opening (15);
The cable path (6) passes through the opening (15) of the magnetic component (4);
A line filter characterized by the above-mentioned. The line filter according to any one of claims 1 to 5,
The press-connecting connector (16) is configured to extract a branch current from the system cable (2) via an electrical connection of the system cable (2) to the shunt component (5). A branch current is smaller than a power supply current flowing through the system cable (2);
A line filter characterized by the above-mentioned.   The line filter according to claim 6, wherein the branch current ranges from 0.1A to 10A.   The line filter according to any one of claims 1 to 7, wherein the line filter (1) is configured to be detachable from the system cable (2).   An assembly comprising a line filter (1) and a system cable (2) according to any of the preceding claims. A method for installing a line filter (1) according to any one of claims 1 to 9 in a system cable (2),
The method comprises:
Inserting the system cable (2) along a cable path (6) defined through the line filter (1), whereby the system cable (2) is inserted into the magnetic component (4). Providing a magnetic coupling of
Tightening the insulation displacement connector (16) around the system cable (2), thereby providing an electrical connection of the system cable (2) to the shunt component (5);
Comprising,
A method comprising:

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